AU2012388629A1

AU2012388629A1 - Networked operation scheduling system for railway vehicles based on electronic intervals

Info

Publication number: AU2012388629A1
Application number: AU2012388629A
Authority: AU
Inventors: Jing Bai; Qing Bai; Wei Bai; Xianbing BAI; Baolong FENG
Original assignee: Individual
Current assignee: Individual
Priority date: 2012-08-27
Filing date: 2012-12-31
Publication date: 2014-12-18
Anticipated expiration: 2032-12-31
Also published as: JP2015522477A; CA2874783A1; US20150191184A1; JP5932152B2; WO2014032218A1; IN2015DN01074A; EP2889201A1; KR20150035691A; AU2012388629B2; EP2889201A4; CN102795250A; KR101653224B1; US9283972B2

Abstract

Disclosed is a networked operation scheduling system for railway vehicles based on electronic intervals, comprising: relay computers at interval endpoints, on-rail communication antennas for distance measurement, on-vehicle response computers and road network computers, wherein each of the relay computers at the interval endpoints is arranged at an endpoint location of each electronic interval; the length of each on-rail communication antenna for distance measurement is equal to that of the electronic interval, with one end of each on-rail communication antenna for distance measurement connected to a relay computer at the interval endpoint and the other end thereof unloaded; an on-vehicle response computer is arranged on each locomotive and communicates with the relay computer at the interval endpoint in the electronic interval occupied by the locomotive through the rail-following communication antenna for distance measurement; the road network computer is connected to the relay computers at the interval endpoints to form a network; and railway security detection sensors are arranged in the electronic intervals. The present invention can solve the problem that it is difficult to perform global scheduling and command in the existing methods for increasing vehicle travelling density and preventing mutual and rear-end collisions based on electronic intervals, and at the same time can achieve information interconnection and interworking among locomotives and between the locomotives and the road network.

Description

Networking operation dispatch system based on electronic zones for rail vehicle Background of the Present Invention Field of Invention The present invention relates to a networking operation dispatch system for preventing 5 rail vehicles from head-on collision and rear-ending collision. Description of Related Arts A Chinese patent application with an application number 201110046202.6 discloses a method for improving operation density of rail vehicle and preventing mutual collision and rear-end collision. The method divides a rail line into equidistant electronic zones, the length of 10 a zone being greater than the shortest safe distance between two running vehicles, and a locomotive passing detection alarm device is installed in each electronic zone, when a locomotive travels at a high speed on the rail, the locomotive passing detection alarm device corresponding to the zone occupied by the locomotive itself will simultaneously access adjacent front and back zones, and determine whether the two adjacent zones are simultaneously 15 occupied by locomotives. If the two adjacent zones are simultaneously occupied by locomotives, the locomotive passing alarm device will send an alarm signal to the locomotives to warn or otherwise take measures. The aforesaid method adopts wired hardware connection of electronic components, and working thereof is processed by a logic gate circuit, whose operation is independent and offline, and information exchanges thereof are offline as well. 20 Therefore, the method is capable of preventing mutual collision and rear-end collision and has an absolute priority. However, the method has disadvantages as follows. A fast determination method for relative distance between locomotives is not provided. In addition, information of locomotives running in each electronic zone cannot be exchanged and transmitted in real time, which brings great difficulties to the unified dispatch and control. Further, the method has 25 disadvantages of insufficiently displaying of dynamic information of locomotives in road network and insufficiently providing external interference for preventing mutual collision and rear-end collision of locomotives. 1 Summary of the Present Invention The present invention provides a networking operation dispatch system based on electronic zones for rail vehicle, so as to solve a problem of difficulties in unified dispatch and control, which exist in the method based on electronic zones for improving operation density of 5 rail vehicle and preventing mutual collision and rear-end collision, so as to accomplish interconnection and intercommunication between locomotives or between the locomotive and the road network. Accordingly, in order to solve the problems mentioned above, technical solutions adopted by the present invention are as follows. 10 A networking operation dispatch system based on electronic zones for rail vehicle comprises: a zone-end relay computer, a communication ranging antenna along rail, a locomotive-mounted response computer and a road networking computer, wherein: the zone-end relay computer is installed on an end of each electronic zone; the communication ranging antenna along rail has an equivalent length to the 15 electronic zone, a first end of the communication ranging antenna along rail is connected with the zone-end relay computer and a second thereof is disposed in the air; the locomotive-mounted response computer is installed on each locomotive and communicates with the zone-end relay computer in the electronic zone occupied by the locomotive via the communication ranging antenna; and 20 the road networking computer connects each zone-end relay computer to form a network. The present invention is an improvement to an application having an application number CN201110046202.6 and a title "Method for improving operation density of rail vehicle and preventing mutual collision and rear-end collision". The aforementioned method disclosed 25 is capable of definitely avoiding locomotive head-on and rear-end collision and has an absolute priority. The networking operation dispatch system of the present invention exchanges and transmits information of locomotive running in each electronic zone in real time via the zone end relay computer and the road networking computer, processes range based localization on the locomotive along rail in the electronic zone, so as to provide convenience for operation 2 dispatch of the locomotive, so as to provide subsidiary for preventing mutual collision and rear end collision, and thus has a secondary priority. A rail security detecting sensor is disposed in the electronic zone for detecting rail hardware or security operation condition, transmitting detected results to the zone-end relay 5 computer in real time or uploading information to the road networking computer, so as to inform relevant units to discover and avoid potential security problems for locomotive running. The networking operation dispatch system of the present invention marks all of the locomotives running in the road network with electronic addresses in an overall network. Each locomotive is precisely processed with range based localization along rail in corresponding 10 electronic zone thereof. Information of all locomotives in the road network is uploaded to the road networking computer via the zone-end relay computer in the electronic zone occupied by the locomotives, so as to provide great convenience for unified dispatch and control. Furthermore, the technical solution is capable of opening or closing a certain electronic zone or turnout in a long distance as well. In addition, installing other rail security detecting sensors has 15 great significance on disaster reduction and prevention and avoiding driving accidents. These and other objectives, features, and advantages of the present invention will become apparent from the following detailed description, the accompanying drawings, and the appended claims. Brief Description of the Drawings 20 Fig. 1 is a schematic view of a networking operation dispatch system based on electronic zones for rail vehicle according to a preferred embodiment of the present invention. In the Fig. 1, Ai, Bi, Ci ...... represent addresses of electronic zones; MAi, MBi, MCi ...... represent zone-end relay computers; MAi, MBi, MCi represent communication ranging antennas along rail; Lai, Lbi, LCi ...... represent zone distances; JI, J2, Jn...... 25 represent locomotive-mounted response computers; and Czz represents road networking computer. 3 Detailed Description of the Preferred Embodiment The present invention provides a networking operation dispatch system based on electronic zones for rail vehicle comprising: a zone-end relay computer, a communication ranging antenna along rail, a locomotive-mounted response computer and a road networking 5 computer. Referring to Fig. 1 of the drawing, the networking operation dispatch for rail vehicle of the present invention is based on electronic zones. In a network, each electronic zone has an address in different sections of rail, and the address is called electronic zone address (Ai, B, Ci......). The electronic zone address is the one and only address. A certain electronic zone 10 address is corresponding to one electronic zone, which actually represents a length of a rail section and is defined as "an electronic position". A plurality of electronic positions are connected in series to form "an electronic character", which actually represents a length of a range of rail connected in series by multiple sections of rail. Any electronic position can be set at a position "1" or a position "0" in the network, wherein setting "1" represents that electronic 15 zone corresponded therewith is occupied or closed, and setting "0" represents that the electronic zone corresponded therewith is free or open. In a node of a rail turnout, three different addresses for the electronic zone must be named, in such a manner that the locomotive which is about to running into the turnout learns that what the combination condition of the forehand turnout is, and that what electronic address of the rail is the turnout going to lead to. Lengths of 20 three adjacent electronic zones which are in peripheries of the three electronic positions must meet a braking length when the locomotive is not allowed to run into the turnout. Lengths of the aforementioned three electronic zones are determined according to rail conditions or control requirements, wherein equivalent distances are not necessary. The zone-end relay computers ( Mai, MBi, MCi...... ) are installed on end positions 25 of each electronic zone. Each end of all the electronic zones has a zone-end relay computer provided thereon, and the zone-end relay computer is installed on one end of the electronic zone. Ends for installing in the electronic zone are divided into "a forward direction end" and "a reverse direction end" according to running directions, so as to distinguish two ends of the electronic zone. The communication ranging antenna along rail (TAi, TBi, TCi......) has an 30 equivalent length to the electronic zone. A first end of the communication ranging antenna along rail is connected with the zone-end relay computer and a second thereof is disposed in the 4 air. The communication ranging antenna along rail, which has an equivalent length to the electronic zone, is lying at a short distance aside the rail. The locomotive-mounted response computer communicates with the zone-end relay computer in one electronic zone therein via the communication ranging antenna along rail. The communication ranging antenna along rail 5 must be installed near the rail to ensure a wireless communication with small gap of the locomotive in real time. The zone-end relay computer is capable of collecting and storing running information of the locomotive in the electronic zone thereof, repeating and communicating on network, sending a ranging signal to the locomotive in the electronic zone thereof After the locomotive responses, a precise distance between the locomotive and the 10 zone-end relay computer is obtained by measuring a length of the communication ranging antenna along rail, which is called zone distance (LAi, LBi, LCi ...... ). The locomotive-mounted response computers (JI, J2, Jn......) are mounted on each locomotive, which is also an identification card of the locomotive and has uniqueness. The locomotive communicates with the zone-end relay computer in the electronic zone occupied by 15 the locomotive via the communication ranging antenna along rail. During operation process of the locomotive, the locomotive-mounted response computer communicates with the zone-end relay computer in the electronic zone occupied by the locomotive in real time. The road networking computer (Czz) is connected with each zone-end relay computer to form a network. Since the zone-end relay computer installed in each electronic zone has a 20 precise electronic address. While forming networking with the road networking computer, a wire or wireless type can be adopted according to security classification and anti-interference ability. In addition, satellite networking can be adopted as well. The road networking computer is capable of switching on/off an electronic zone or turnout in a long distance, so as to control that whether the locomotive can run into the electronic zone. 25 A rail security detecting sensor is disposed in the electronic zone. The rail security detecting sensor transmits information to the zone-end relay computer, marks the information and then uploads the information with the geographic coordinate to the road networking computer via the zone-end relay computer. The rail security detecting sensor is for detecting rail deformation caused by natural disasters such as collapse or flood, or other accident 30 potentials that do not accord with security operation condition. If conditions mentioned above happen, the rail security detecting sensor sends information to the zone-end relay computer, and then uploads the information to the road networking computer via the zone-end relay computer. 5 Combined with the accompanying drawings, principle of the networking operation dispatch system of the present invention is specifically illustrated as follows. Fig. 1 shows a turnout node, wherein electronic addresses are allocated to three sections of rail, which are respectively Ai, Bi and Ci. 5 When a locomotive Jn travels in a electronic zone, the locomotive is capable of learning that whether two adjacent zones in front and behind are occupied by other locomotive, if yes, two locomotives alarm simultaneously and directly exchange information via zone-end relay computers, wherein the information comprises a distance between the two locomotives, a relative velocity thereof and an early warning level of head-on collision and rear-ending 10 collision, so as to warn a driver in tine or otherwise automatically take measures. The zone-end relay computer corresponded to the two locomotives is capable of transmitting the early warning information mentioned above combined with geographic coordinates thereof to the road networking computer. When two locomotives drive into adjacent electronic zones, the two locomotives 15 alarm simultaneously and directly exchange information offline, wherein a distance between the two locomotives is obtained by calculating the electronic address and the zone distance: S=L[Ai-(Ai-1)]+L(Ai)-L(Ai-1) wherein Ai and Ai-1 respectively represent zone-end coordinates; L[Ai-(Ai-1)] is a length of the electronic zone Ai-1; wherein early warning levels of the two locomotives are 20 obtained by calculating further according to relative velocity of the two locomotives. One skilled in the art will understand that the embodiment of the present invention as shown in the drawings and described above is exemplary only and not intended to be limiting. It will thus be seen that the objects of the present invention have been fully and effectively accomplished. Its embodiments have been shown and described for the purposes of 25 illustrating the functional and structural principles of the present invention and is subject to change without departure from such principles. Therefore, this invention includes all modifications encompassed within the spirit and scope of the following claims. 6

Claims

1. A networking operation dispatch system based on electronic zones for rail vehicle, comprising: a zone-end relay computer, a communication ranging antenna along rail, a locomotive-mounted response computer and a road networking computer, 5 wherein the zone-end relay computer is installed on an end of each electronic zone; wherein the communication ranging antenna along rail has an equivalent length to the electronic zone, a first end of the communication ranging antenna along rail is connected with the zone-end relay computer and a second thereof is disposed in the air; wherein the locomotive-mounted response computer is installed on each locomotive 10 and communicates with the zone-end relay computer in the electronic zone occupied by the locomotive via the communication ranging antenna; and wherein the road networking computer connects each zone-end relay computer to form a network.

2. The system, as recited in claim 1, wherein a rail security detecting sensor is disposed 15 in the electronic zone, for uploading information to the road networking computer. 7